# Difference between revisions of "Polygons in Spherical and Euclidean Geometry Exploration"

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{{Objective| | {{Objective| | ||

− | Explore | + | Explore the existence of certain types of polygon in Euclidean geometry and spherical geometry. |

+ | Understand the importance of definitions.}} | ||

− | ===A. | + | ===A. Biangles=== |

− | In Spherical geometry | + | In Spherical geometry, two sided polygons (2-gons) exist. They are also called biangles, bi-gons, and lunes. |

− | # Draw an example of a 2 gon on a sphere. | + | # Draw an example of a 2-gon on a sphere. |

# Why are there no 2-gons in Eucidean geometry? Which axiom is “responsible” for the difference between the two geometries? | # Why are there no 2-gons in Eucidean geometry? Which axiom is “responsible” for the difference between the two geometries? | ||

− | |||

===B. Triangles=== | ===B. Triangles=== | ||

In Euclidean geometry we can define | In Euclidean geometry we can define | ||

− | * A | + | * A {{define|regular triangle}}: any 3-gon with congruent sides and angles. |

− | * | + | At least two definitions of {{define|equilateral triangle}} are possible: |

− | * | + | * ET1: a triangle with all 3 sides congruent. |

− | * An | + | * ET2: a triangle with three 60 degree angles. |

− | In Euclidean geometry all | + | Finally, define |

− | # Which of these triangles exist in | + | * An {{define|equiangular triangle}}: a triangle with three congruent angles. |

− | # | + | In Euclidean geometry all four of these definitions describe the same polygons. |

− | + | # Which of these triangles exist in spherical geometry? | |

+ | # Of the ones that exist, do they define the same shapes? Or could they be different? Explain. | ||

===C. Squares=== | ===C. Squares=== | ||

− | In Euclidean geometry we can define a square in at least | + | In Euclidean geometry we can define a {{define|square}} in at least two different ways: |

− | * | + | * S1: A 4-gon with congruent sides and congruent angles. |

− | * | + | * S2: A 4-gon with congruent sides and all angles measuring 90°. |

− | + | Compare this to: | |

− | * A regular 4-gon: A 4 gon with congruent sides and congruent angles | + | * A regular 4-gon: A 4-gon with congruent sides and congruent angles. |

In Euclidean geometry these are one and the same thing. | In Euclidean geometry these are one and the same thing. | ||

− | # Which | + | # Which of these shapes exist in spherical geometry? |

# Would you say squares exist on the sphere? Why or why not? | # Would you say squares exist on the sphere? Why or why not? | ||

− | ===D. | + | ===D. Rectangles=== |

− | In Euclidean | + | In Euclidean geometry we can define a rectangle in several different ways: |

− | * R1: A 4-gon with all interior angles | + | * R1: A 4-gon with all interior angles 90°. |

* R2: A 4-gon with all interior angles congruent. | * R2: A 4-gon with all interior angles congruent. | ||

− | * R3: A 4-gon with | + | * R3: A 4-gon with two pairs of parallel sides and all angles congruent. |

# Which of these definitions cannot possibly work on the sphere? | # Which of these definitions cannot possibly work on the sphere? | ||

− | # Is there one that | + | # Is there one that defines 4-gons which are possible to construct on the sphere? What will such a 4-gon look like? What would you call it? |

===E. Parallelograms=== | ===E. Parallelograms=== | ||

− | In Euclidean | + | In Euclidean geometry the following statements can all be used to define a parallelogram. They all describe the exact same family of polygons. |

− | * P1: | + | * P1: A quadrilateral with opposite sides parallel and equal in length, and opposite angles equal. |

* P2: A quadrilateral with both pairs of opposite sides parallel and equal in length. | * P2: A quadrilateral with both pairs of opposite sides parallel and equal in length. | ||

− | * P3: A | + | * P3: A quadrilateral with opposite sides parallel. |

− | * P4: A | + | * P4: A quadrilateral with opposite sides congruent (theorem). |

− | * P5: A | + | * P5: A quadrilateral with opposite angles congruent (theorem). |

− | * P6: A | + | * P6: A quadrilateral whose diagonals bisect one another (theorem). |

# Which definition cannot possibly work on the sphere? Why? | # Which definition cannot possibly work on the sphere? Why? | ||

− | # Of the other definitions, which ones correspond to polygons we can construct on the sphere? Can they be used interchangeably? What would you call | + | # Of the other definitions, which ones correspond to polygons we can construct on the sphere? Can they be used interchangeably? What would you call these polygons? |

+ | |||

+ | {{handin}} | ||

+ | [[category:Non-Euclidean Geometry Explorations]] |

## Latest revision as of 10:25, 2 November 2011

**Objective:**

Explore the existence of certain types of polygon in Euclidean geometry and spherical geometry. Understand the importance of definitions.

### A. Biangles

In Spherical geometry, two sided polygons (2-gons) exist. They are also called biangles, bi-gons, and lunes.

- Draw an example of a 2-gon on a sphere.
- Why are there no 2-gons in Eucidean geometry? Which axiom is “responsible” for the difference between the two geometries?

### B. Triangles

In Euclidean geometry we can define

- A
**regular triangle**: any 3-gon with congruent sides and angles.

At least two definitions of **equilateral triangle** are possible:

- ET1: a triangle with all 3 sides congruent.
- ET2: a triangle with three 60 degree angles.

Finally, define

- An
**equiangular triangle**: a triangle with three congruent angles.

In Euclidean geometry all four of these definitions describe the same polygons.

- Which of these triangles exist in spherical geometry?
- Of the ones that exist, do they define the same shapes? Or could they be different? Explain.

### C. Squares

In Euclidean geometry we can define a **square** in at least two different ways:

- S1: A 4-gon with congruent sides and congruent angles.
- S2: A 4-gon with congruent sides and all angles measuring 90°.

Compare this to:

- A regular 4-gon: A 4-gon with congruent sides and congruent angles.

In Euclidean geometry these are one and the same thing.

- Which of these shapes exist in spherical geometry?
- Would you say squares exist on the sphere? Why or why not?

### D. Rectangles

In Euclidean geometry we can define a rectangle in several different ways:

- R1: A 4-gon with all interior angles 90°.
- R2: A 4-gon with all interior angles congruent.
- R3: A 4-gon with two pairs of parallel sides and all angles congruent.

- Which of these definitions cannot possibly work on the sphere?
- Is there one that defines 4-gons which are possible to construct on the sphere? What will such a 4-gon look like? What would you call it?

### E. Parallelograms

In Euclidean geometry the following statements can all be used to define a parallelogram. They all describe the exact same family of polygons.

- P1: A quadrilateral with opposite sides parallel and equal in length, and opposite angles equal.
- P2: A quadrilateral with both pairs of opposite sides parallel and equal in length.
- P3: A quadrilateral with opposite sides parallel.
- P4: A quadrilateral with opposite sides congruent (theorem).
- P5: A quadrilateral with opposite angles congruent (theorem).
- P6: A quadrilateral whose diagonals bisect one another (theorem).

- Which definition cannot possibly work on the sphere? Why?
- Of the other definitions, which ones correspond to polygons we can construct on the sphere? Can they be used interchangeably? What would you call these polygons?

**Handin:**
A sheet with answers to all questions.